Water Data Needs and Applications in the Private Sector Robert Annear, Vice President, Ph.D., P.E. Water is our nature GRN Forum: Global Water - 2010 and Beyond Oct 21 2010 - Oct 22 2010
Introduction Our Mission: Transforming Knowledge of Water Into Value and Welfare Modeling the world of water Watersheds & Rivers Urban & Industry Marine & Coastal Globally 1,000 Staff (850 Professionals) Turnover ~$90 million Offices in 26 Countries DHI North America (US and Canada) 38 Staff Turnover ~$8 million 11 offices in North America
Activity by Category 6% 5% 15% Performance Contract Commissioned R&D (R&D Contracts) Software Sales 71% 3% Equipment Sales (Other Products) Specialized Consultancy
Our Clients Federal US Army Corps of Engineers, NASA, FEMA, and Bureau of Reclamation State Local Department of Environmental Protection, FL Water Resources Departments, CA and ID Department of Land and Natural Resources, HI California Coastal Conservancy, CA Cities Vancouver, Springfield, Redmond, Chicago, LA Counties King County, Collier, Broward, FL Flood Control Districts Alameda County FCD, CA Water Management Districts South Florida Ports Long Beach, CA Private Power Utilities Idaho Power, ID Developers Biale, ID Non-Profit McKenzie River Trust, OR
Water data How data is needed and applied in the private sector Periodic Studies and Evaluations Capital Improvement Programs Sanitary systems Storm water systems Water distribution systems Source water feasibility studies New Infrastructure and Upgrades (pipes, bridges, levees) Feasibility studies Design testing Environmental impacts Water Rights New water rights Water availability studies
Water data How data is needed and applied in the private sector Ongoing Operations Real Time Monitoring and Control Systems Water distribution and sanitary systems Storm water control systems Hydropower operations Flood control Efficient Irrigation Water Delivery Monitor flow Gate operations Weather conditions Flood Control Precipitation Flows Water levels Efficient Port Operations Tides (water level), River flows Water quality
Water data availability Limitations You never have enough data. Collection is expensive Instrumentation costs Maintenance costs Staffing expertise Interpretation QA/QC of the data Data handling Staffing expertise Sustainability Often the data does not become useful until after years of collection Must be committed in some cases to long term monitoring (regulatory compliance)
What is water modeling? Using computers to solve numerical equations representing the physical processes of water movement (conservation of mass, momentum) within the natural and built environments Common models: Hydrologic models Hydraulic models (hydrodynamic models) Water quality models Sediment transport models
Why Model? Water modeling is used to help society solve problems and better manage water resources Many times the system is so complex that its too expensive to collect data everywhere so models are used to better understand these systems and fill in the gaps Other uses Forecast future conditions Assess alternative design or management scenarios water rights transfer climate change ecosystem restoration urban infrastructure improvements
Overview of computer modeling tools 1. Hydrologic models a) Compute water budget components (evapotranspiration, infiltration, rainfall-runoff, etc.) b) Provide inflows to hydraulic models Increasing complexity 2. One-dimensional (1D) hydraulic models a) Used to compute discharge and stage b) Use cross section and structure data 3. Two-dimensional (2D) hydraulic models a) More realistic floodplain flow representation b) Use grids or meshes of topographic/bathymetric data 4. Three-dimensional (3D) hydraulic models
Data Needs The more complex the problem, often the more complex the model and the more data needed to support it. Bathymetry Topography (LiDAR) Water level Flow Velocity Facilities operations (dams, gates, weirs etc.) Temperature Water quality (nutrients, dissolved oxygen algae) GIS data (land use, vegetation, infrastructure) Snow depth Precipitation, Weather radar Meteorology (air temperature, wind speed and direction, solar radiation) Soil characteristics Sediment characteristics (size, type etc.) Groundwater flow, temperature and water quality Aerial photographs
Where is data needed in modeling? The more complex the problem, often the more complex the model and the more data needed to support it. Data Analyses Studies and analyses to define the problem and understand a physical system Model Development Building a numerical model of the real world system Model Calibration Calibrating the model to ensure its simulating reality accurately Model Scenario Development Using the model to try out management alternatives (land use change, reservoir operations)
Where do we get the data? Federal US Army Corps of Engineers Bureau of Reclamation US Geological Survey US EPA NOAA: River Forecast Centers, National Weather Service State Local Department of Environmental Protection\Quality Water Resources Departments Department of Land and Natural Resources California Coastal Conservancy Regional Agencies: Metro/Tri County Cities Counties Flood Control Districts Water Management Districts Ports Private Power Utilities Other Consultants Non-Profit McKenzie River Trust The Nature Conservancy
Data handling and storage Quality Assurance and Quality Control of data Since DHI receives data from a variety of sources and uses them to build a model we must take ownership of the data just as we take responsibility for the model. Handling and Archiving Spatial data GIS Layers, LiDAR, Model Grids/Meshes Time series data Databases, processing, MS Excel files Real time control/management systems Delivery to client A client s objectives often require data files to be provided differently than used for the study. Ownership once in the client s hands? Long term storage of project files at DHI.
Thank you